Process and apparatus for producing sponge iron

ABSTRACT

A process and an apparatus for producing sponge iron from iron-oxide-containing material in lump form by direct reduction in a reduction shaft using a reducing gas, wherein the entire reducing gas is introduced by means of a number of reducing gas distribution ducts in a star-like arrangement or arranged parallel to one another, preferably into the lower quarter of the reduction shaft, and evenly distributed over the entire cross-section of the reduction shaft.

CROSS REFERENCE TO RELATED APPLICATION

The present application is a divisional of U.S. patent application Ser. No. 12/666,893, filed Mar. 11, 2010, issued on Feb. 28, 2012 as U.S. Pat. No. 8,124,005, which was a U.S.C. §371 National Phase conversion of PCT/EP2008/004623, filed Jun. 10, 2008, which, in turn, claims priority of Austrian Application No. A 1003/2007, filed Jun. 28, 2007, the entire contents of which are hereby incorporated by reference.

BACKGROUND OF THE INVENTION

The invention relates to a process and an apparatus for producing sponge iron from iron-oxide-containing material in lump form by direct reduction in a reduction shaft using a reducing gas.

When producing sponge iron, also referred to as direct reduction iron, by direct reduction, the reduction shaft is charged from above with iron oxides in lump form, such as pellets and/or lump ores, through which a rising reducing gas is made to flow on the basis of the counterflow principle. The reducing gas that is introduced into the reduction shaft, preferably being at a temperature of 750 to 900° C., containing dust and rich in carbon monoxide and hydrogen, in particular containing 70 to 90% CO and H₂, is preferably produced in a fusion gasifier or in some other gas generator. In this way, the iron oxide in lump form is reduced completely or partially to sponge iron and a degree of metallization of from 80% to over 95% of the sponge iron can be achieved.

In the apparatuses and processes that are known from the prior art, the reducing gas is introduced at the circumference of the reduction shaft, for example by means of an annular duct that is formed by refractory bricks, known as a bustle duct. When the reducing gas is introduced by means of such a bustle duct, however, less reducing gas reaches the middle of the reduction shaft, and so the degree of metallization in the outer region is higher than it is toward the middle of the reduction shaft. Since a poured fill with a lower degree of metallization has a greater bulk weight than such a fill with a higher degree of metallization, and also breaks down to a greater extent, the motion of the filling process is concentrated toward the middle of the reduction shaft. This centrally concentrated motion has the effect that the uneven distribution of the specific amount of reducing gas is further exacerbated. The uneven distribution of the reducing gas is all the greater the larger the diameter of the reduction shaft and the greater the amount of dust contained in the reducing gas. Furthermore, the bustle duct formed by refractory bricks requires a lining, which is costly, susceptible to wear and therefore keeps having to be renewed.

In DE2628447A1, in addition to the bustle duct, a central feeding device below the level of the bustle duct is described. According to EP0904415A1, additional reducing gas inlets in the form of downwardly open ducts or obliquely downwardly directed lines with an open inner end are likewise located below the level of a bustle duct.

Although these apparatuses provide a better supply of reducing gas toward the middle, the reduction shaft with the bustle duct and gas distribution ducts in the middle is costly and still has the disadvantage that the reducing gas is introduced at the same pressure at two different levels, as a specific result of which more reducing gas per m² is introduced through the higher inlet, since the upward path of the gas is shorter there. Less reducing gas specifically means, however, a lower degree of metallization of the fill in the middle of the reduction shaft.

DE 28 10 657 discloses a reduction shaft which has in addition to a bustle pipe devices for the introduction of process gases, such as for example natural gas. Disadvantages in this case are the uneven introduction of the reducing gas via the bustle pipe and the high cost of the apparatus.

WO 00/36159 describes a reduction shaft in which reducing gas is introduced at two levels or in two zones. Disadvantages are, in particular, the great technical cost of the plant and the high requirements for controlling the introduction of the reducing gas.

SUMMARY OF THE INVENTION

The object of the present invention is therefore to provide a simple process and a simple apparatus with which uniform distribution of the reducing gas, and consequently uniform metallization, are obtained without the need for a bustle duct and the associated costly and wear-susceptible lining of the reduction shaft.

The subject matter of the invention is accordingly a process for producing sponge iron from iron-oxide-containing material in lump form by direct reduction in a reduction shaft using a reducing gas, which process is characterized in that the entire reducing gas is introduced by means of a number of reducing gas distribution ducts in a star-like arrangement or arranged parallel to one another, preferably into the lower quarter of the reduction shaft.

To carry out the process, iron-oxide-containing material in lump form, such as pellets and/or lump ore, is introduced into a reducing shaft from above. In addition, gas, known as reducing gas, preferably at a temperature of 750 to 900° C., produced in particular in a fusion gasifier, containing dust and rich in carbon monoxide and hydrogen, in particular containing 70 to 90% CO and H₂, is introduced via reducing gas distribution ducts, preferably in the lower quarter of the reduction shaft. The reducing gas introduced rises upward and thereby reduces the iron oxide to form sponge iron. The exclusive introduction of the entire reducing gas via the reducing gas distribution ducts in a star-like arrangement or arranged parallel to one another brings about a uniform distribution of the reducing gas and the dust contained in it over the entire cross section of the reduction shaft.

The reducing gas distribution ducts are downwardly open half-pipe shells that are fastened on skid pipes and have downwardly extended parallel walls. When the reduction shaft is charged from above with the iron oxide fill, a space that is free from fill is created under the half-pipe shells and from there the reducing gas passes uniformly into the fill.

The reducing gas distribution ducts may be in a star-like arrangement and be of the same length or of different lengths. With preference, they are of different lengths, the shorter reducing gas distribution ducts preferably being overhung-mounted and the longer reducing gas distribution ducts preferably being supported by water-cooled supporting pipes. A star-like arrangement means that a number of reducing gas distribution ducts, preferably 4 to 12, in particular 8, extend from the wall of the reduction shaft into the interior of the reduction shaft, all the reducing gas distribution ducts being directed toward the center point of the reduction shaft. With preference, a longer reducing gas distribution duct is then respectively arranged alongside a shorter duct, the longer reducing gas distribution ducts preferably being fitted over the discharge hoppers for the sponge iron. Arranged at the lower end of the discharge hoppers are preferably water-cooled discharge worms or other discharge devices.

The reducing gas distribution channels are preferably on one level.

In the case of an arrangement in which a longer reducing gas distribution duct is respectively arranged alongside a shorter duct, it is however also possible with preference to fit the shorter, overhung-mounted reducing gas distribution ducts just above the longer, supported reducing gas distribution ducts. This may possibly be of advantage when using ores that have a tendency to break up and for bridges to form. It is important here that the reducing gas distribution ducts at different heights lie so closely one above the other that there is virtually no difference in pressure when the reducing gas is introduced.

The reducing gas distribution ducts may also be arranged in parallel and be of the same length or of different lengths. With preference, the reducing gas distribution ducts are in this case on one level. In the case of small diameters of the reduction shaft, the entire reducing gas is preferably introduced via a number of reducing gas distribution ducts, preferably 2 to 8, in particular 4, arranged in parallel, extending continuously from the wall of the reduction shaft to the opposite wall of the reduction shaft. In the case of reduction shafts of average size, there may additionally be two reducing gas distribution ducts lying opposite each other, directed toward the middle along the diameter of the shaft and parallel to the other reducing gas distribution ducts extending continuously from the wall of the reduction shaft to the opposite wall of the reduction shaft. These additional, shorter reducing gas distribution ducts are with preference supported by water-cooled supporting pipes.

Further subject matter of the invention is an apparatus for producing sponge iron from iron-oxide-containing material in lump form by direct reduction in a reduction shaft (1) using a reducing gas, which apparatus is characterized in that the entire reducing gas is fed in via a number of reducing gas distribution ducts (2 a, 2 b) in a star-like arrangement, preferably in the lower quarter of the reduction shaft (1), or reducing gas distribution ducts (2) arranged parallel to one another, preferably in the lower quarter of the reduction shaft (1).

The invention is explained in more detail below on the basis of exemplary embodiments that are represented in the figures, in which:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a vertical section through a reduction shaft (1) in which a reducing gas distribution duct (2 a, 2 d) and a reducing gas distribution duct (2 b) are depicted,

FIG. 2 shows a vertical section through a reducing gas distribution duct (2) with a skid pipe (3) for the introduction of the reducing gas into the fill,

FIG. 3 shows a horizontal section through the reduction shaft (1) as shown in FIG. 1 above the reducing gas distribution ducts (2 a) and (2 b) in a star-like arrangement,

FIG. 4 shows a horizontal section through a second embodiment of a reduction shaft (1) as shown in FIG. 1 above the reducing gas distribution ducts (2 c) arranged in parallel and

FIG. 5 shows a horizontal section through a third embodiment of a reduction shaft (1) as shown in FIG. 1 above the reducing gas distribution ducts (2 c) and (2 d) arranged in parallel.

DESCRIPTION OF A PREFERRED EMBODIMENT

A cylindrical reduction shaft (1), which is charged from above with iron-oxide-containing material in lump form via distribution pipes (5), is provided in the lower quarter of the shaft with a plurality of reducing gas distribution ducts (2), through which a reducing gas is introduced into the reduction shaft (1). At the lower end of the reduction shaft (1), the material that has been reduced to sponge iron is discharged through discharge hoppers (6). Arranged at the lower end of the discharge hoppers (6) are water-cooled discharge worms or other discharge devices, which are not represented in the Figures.

Reducing gas distribution ducts (2) are downwardly open half-pipe shells with downwardly extended parallel walls, which, as can be seen in FIG. 4, are fastened on skid pipes (3), which are cooled inside, preferably by water.

The reducing gas distribution ducts (2) may be in a star-like arrangement, e.g., an arrangement as in FIG. 3.

The reducing gas distribution ducts (2 a, 2 b) in a star-like arrangement may be of the same length or may be of different lengths as shown in FIG. 3. With preference, they are of different lengths. With particular preference, longer reducing gas distribution ducts (2 a) alternate with shorter reducing gas distribution ducts (2 b), as represented in FIG. 3. Then, the middle region and part of the outer region, in particular about 50%, of the reduction shaft (1) is supplied with the reducing gas via the longer reducing gas distribution ducts (2 a) and the remaining part of the outer region is supplied with the reducing gas via the shorter reducing gas distribution ducts (2 b). Longer skid pipes (3), as are required for longer reducing gas distribution ducts (2 a), are usually additionally supported by water-cooled supporting pipes (4), as shown in FIG. 1, which are fastened to the bottom of the reduction shaft (1), while the skid pipes (3) of the shorter reducing gas distribution ducts (2 b) are preferably overhung-mounted.

In the case of reduction shafts (1) with a star-like arrangement of the reducing gas distribution ducts (2 a, 2 b) and having a relatively lower number of discharge hoppers (6), preferably fewer than 8, in particular 4, the longer reducing gas distribution ducts (2 a) are arranged with preference over the discharge hoppers (6) and the shorter ducts (2 b) are arranged with preference over the spaces between the discharge hoppers (6).

The reducing gas distribution ducts (2 a, 2 b) are preferably arranged on one level along the shaft as in FIG. 1.

In the case of an arrangement in which a longer reducing gas distribution duct (2 a) is respectively arranged alongside a shorter duct (2 b), it is however also possible with preference to arrange the shorter, overhung-mounted reducing gas distribution ducts (2 b), as shown in a phantom depiction in FIG. 1, just above the longer, supported reducing gas distribution ducts (2 a). This may possibly be of advantage when using ores that have a tendency to break up and for bridges to form. It is important here that the reducing gas distribution ducts (2 a, 2 b) at different heights lie so closely one above the other that there is virtually no difference in pressure when the reducing gas is introduced.

The reducing gas distribution ducts (2) may also be arranged parallel to one another as in FIG. 4 or 5.

The reducing gas distribution ducts (2 c, 2 d) arranged parallel to one another may be of the same length or of different lengths and lie with preference on one level. If the reducing gas distribution ducts (2) are arranged in parallel, it is sufficient, in particular in the case of small reduction shafts, for there to be two or more reducing gas distribution ducts (2 c) arranged parallel to one another, made to extend continuously from the wall of the reduction shaft to the opposite wall of the reduction shaft as in FIG. 5.

In the case of reduction shafts of average size, for instance in the case of reduction shafts of 6 to 8 m in diameter, it is advantageous to arrange two further reducing gas distribution ducts (2 d) along the diameter of the reduction shaft (1) and lying opposite, and to arrange the remaining reducing gas distribution ducts (2 c) parallel thereto and preferably extending continuously from the wall of the reduction shaft to the opposite wall of the reduction shaft, as shown in FIG. 5. The reducing gas distribution ducts (2 d) are in this case preferably supported by water-cooled supporting pipes (4), in a way analogous to the support of the reducing gas distribution ducts (2 a) in a star-like arrangement. 

1. A process for producing sponge iron starting with iron-oxide-containing material in lump form, the process comprising: arranging a plurality of reducing gas distribution ducts inside of a reduction shaft, wherein the gas distribution ducts extend into an interior of the reduction shaft away from a periphery of the reduction shaft and are arranged in a star-like arrangement or are arranged parallel to one another for attaining even distribution of a reduction gas over an entire cross-section of the reduction shaft; introducing the iron-oxide-containing material in the lump form into the reduction shaft; and introducing an entire supply of reducing gas for the process via the plurality of the reducing gas distribution ducts for attaining even distribution of the reducing gas over the entire cross-section of the reduction shaft.
 2. The process as claimed in claim 1, wherein the arranging of the gas distribution ducts is such that a longer one of the ducts is arranged alongside a shorter one of the ducts, such that the longer ones of the gas distribution ducts alternate with the shorter ones of the gas distribution ducts around the shaft so as to attain the even distribution of the reduction gas over the entire cross-section of the reduction shaft.
 3. The process as claimed in claim 1, wherein the arranging of the gas distribution ducts is such that a longer one of the ducts is arranged alongside a shorter one of the ducts when viewed from a perspective at a top or at a bottom of the shaft, such that the longer ones of the gas distribution ducts alternate with the shorter ones of the gas distribution ducts around the shaft so as to attain the even distribution of the reduction gas over the entire cross-section of the reduction shaft, wherein the arranging the shorter length reducing gas distribution ducts comprises positioning the shorter length reducing gas distribution ducts at a higher level in the reduction shaft, the higher level being a level just above a lower level of the longer reducing gas distribution ducts, and wherein the longer and the shorter gas distribution ducts are positioned at levels selected such that virtually no difference in the pressure exists when reducing gas is introduced through the ducts.
 4. The process as claimed in claim 1, wherein the ducts are arranged parallel to one another and extend across the shaft oriented parallel to one another.
 5. The process as claimed in claim 1, wherein the reduction shaft has a lower quarter and the ducts are at or substantially at a level along the shaft so as to enter and extend into the lower quarter of the reduction shaft.
 6. The process as claimed in claim 1, wherein the reducing gas distribution ducts are formed as downwardly open path pipe shells and the iron-oxide-containing material is charged into the shaft via the gas distribution ducts such that spaces free from fill comprised of the lump form material are formed under the reducing gas distribution ducts.
 7. The process as claimed in claim 1, wherein the introducing of the iron-oxide-containing material into the reducing shaft is from above the gas distribution ducts.
 8. The method as claimed in claim 1, wherein the plurality of reducing gas distribution ducts are positioned at one level inside of the reduction shaft.
 9. A method of producing sponge iron starting with iron-oxide-containing material in lump form, the method comprising: introducing the iron-oxide-containing material in the lump form into a reduction shaft via a plurality of reducing gas distribution ducts positioned inside of the reduction shaft, and the gas distribution ducts extend into the reduction shaft away from a periphery of the reduction shaft and are positioned in a star-like arrangement or are positioned parallel to one another for attaining even distribution of the reduction gas over an entire cross-section of the reduction shaft; and introducing an entire supply of reducing gas for the process via the plurality of the reducing gas distribution ducts so as to attain even distribution of the reducing gas over the entire cross-section of the reduction shaft.
 10. The method as claimed in claim 9, wherein the gas distribution ducts are positioned such that a longer one of the ducts is arranged alongside a shorter one of the ducts, such that the longer ones of the gas distribution ducts alternate with the shorter ones of the gas distribution ducts around the shaft so as to attain the even distribution of the reduction gas over the entire cross-section of the reduction shaft.
 11. The method as claimed in claim 9, wherein the gas distribution ducts are positioned such that a longer one of the gas distribution ducts is arranged alongside a shorter one of the ducts when viewed from a perspective at a top or at a bottom of the shaft, such that the longer ones of the gas distribution ducts alternate with the shorter ones of the gas distribution ducts around the shaft so as to attain the even distribution of the reduction gas over the entire cross-section of the reduction shaft, wherein the shorter length reducing gas distribution ducts are positioned at a higher level in the reduction shaft, the higher level being a level just above a lower level of the longer reducing gas distribution ducts, and wherein the longer and the shorter gas distribution ducts are positioned at levels selected such that virtually no difference in the pressure exists when reducing gas is introduced through the ducts.
 12. The method as claimed in claim 9, wherein the gas distribution ducts are arranged parallel to one another and extend across the shaft oriented parallel to one another.
 13. The method as claimed in claim 9, wherein the reduction shaft has a lower quarter and the gas distribution ducts are at or substantially at a level along the shaft so as to enter and extend into the lower quarter of the reduction shaft.
 14. The method as claimed in claim 9, wherein the reducing gas distribution ducts are formed as downwardly open path pipe shells and the iron-oxide-containing material is charged into the shaft via the gas distribution ducts such that spaces free from fill comprised of the lump form material are formed under the reducing gas distribution ducts.
 15. The method as claimed in claim 9, wherein the introducing of the iron-oxide-containing material into the reducing shaft is from above the gas distribution ducts.
 16. The method as claimed in claim 9, wherein the plurality of reducing gas distribution ducts are positioned at one level inside of the reduction shaft. 